7.02 Scatterplots and lines of fit

Formulate a question that could be answered by the data.

We are given the number of tickets sold and the corresponding gross revenue from selling those tickets. Think of a question that could be answered by analyzing the relationship between these two variables.

One example would be, "What is the relationship between the number of tickets sold and the gross revenue from the tickets?" or more specifically, "Does a high number of tickets sold correspond to a high gross revenue?"

We could also formulate questions about predicting the gross revenue, such as "What is the predicted gross revenue if 80\,000 tickets are sold?"

Create a scatterplot of the data.

We can use technology to construct the scatterplot by following these steps:

1. In the GeoGebra Statistics calculator, enter the data into two columns, one column for the independent variable and one column for the dependent variable.

2. Select all of the cells containing data and choose "Two Variable Analysis."

3. Use the settings to adjust the scatterplot as needed.

In this scenario, the number of tickets sold is the independent variable and gross revenue is the dependent variable.

1. Enter the data into two columns.

   

2. Select all of the cells containing data and choose "Two Variable Regression Analysis."

   

After the scatterplot is generated, we can adjust the scales by clicking the settings icon.

• Select "Graph" in the upper right corner, then deselect the box that says "Automatic Dimensions".

• Checking the box that says "Show Grid" will add grid lines to the graph.

• We could set the X Step (horizontal scale) to 1000 and the Y step (vertical scale) to 0.1, then select "Show Grid" to easily identify which point represents which pair of values.

Find the line of best fit.

We can use technology to find the line of best fit. After following the steps in part (b), we can find the equation of the best fit line by changing the regression model at the bottom of the screen to "Linear".

Find the Regression model dropdown list at the bottom part of the screen, and select "Linear".

The equation of the line of best fit is y=0.0001x-0.0701.

Although the coefficients seem like very small numbers, remember that our dependent variable is in millions. If we had written out all the place values, the coefficients in the equation would have been very large.

Use the correlation coefficient to evaluate the strength of the model.

We can use technology to find the correlation coefficient. After following the steps in part (c), select the \Sigma x icon.

We can use this diagram to evaluate the strength of the model.

Select "Show statistics". The correlation coefficient is represented by r.

The correlation coefficient is r=0.9253, which means there is strong positive correlation between the variables. This tells us that the model can make relatively accurate predictions.

Even when two variables have a strong relationship and r is close to 1 or -1, we cannot say that one variable causes change in the other variable. Causation can only be determined from an appropriately designed statistical experiment.

Use the model to answer the question you formulated in part (a).

The statistical question from part (a) is, "Does a high number of tickets sold correspond to a high gross revenue?" To answer this question, we can describe the correlation in context and discuss the strength of the correlation that we found in the previous part.

The scatterplot shows a strong, positive linear correlation between the variables. This means that a high number of tickets sold does correspond to a high gross revenue.

Note that the term "high" is relative, so a more specific description of the number of tickets sold or the amount of gross revenue may be better when communicating the results of the analysis.

For example, we might say, "When the number of tickets sold increased by about 14\,000 tickets, the gross revenue from those ticket sales increased by about \$1.6 million."

Predict the gross revenue if a concert sells 77\,000 tickets.

We can use technology and the line of best fit from part (c) to predict the gross revenue given the number of tickets sold. Remember that the number of tickets will be the input, and the output will be the gross revenue in millions of dollars.

To use the graph to predict the gross revenue, we can draw a vertical line at x=77\,000 until it intersects with the line of best fit. Then, we can visually trace a straight line to determine the corresponding y-value.

At the bottom of the graph, we can enter x=77\,000, and it will use the line of best fit to calculate the y-value.

The predicted gross revenue if a concert sells 77\,000 tickets is \$9.17 \text{ million}.

If we had used the line of best fit from part (c) and calculated the gross revenue by hand, we would have gotten a very different result.

The reason this is different from the value we got when using technology is because the coefficients were rounded in our line of best fit. When calculated with the actual line of best fit, the calculator does not round the coefficients, making its result more accurate.

Describe a possible method that the principal could use to collect the data.

The data collection methods we have studied are surveys, observations, scientific experiments, polls, or questionnaires. Another possible method is researching existing data on class sizes and attention time per small group.

As a school principal, it is possible that the data was collected firsthand. Teachers are most likely not tracking the time they spend with small groups since they are focused on teaching the material, so the principal probably would not use a survey, poll, or questionnaire.

One way the principal may have collected the data is throughout observation. They may have been able to observe various class periods of varying class sizes and tracked the amount of time each teacher was able to spend with small groups of students.

Have you ever noticed a principal or assistant principal observing one of your classes? What kind of data do you think they were collecting?

The equation of the line of best fit shown is y=-0.401x+18.3, and the correlation coefficient is r=-0.95. Could this line of best fit be used to make reasonable predictions? Explain.

When considering the reasonableness of a model, we want to analyze the correlation coefficient. The closer the correlation coefficient is to -1 or 1, the stronger the linear correlation between the variables.

The correlation coefficient of this model is -0.95 which indicates a strong, negative linear correlation between the variables. Because the correlation is strong, the actual data values are close to the line which makes it a relatively reliable model for making predictions.

Describe the relationship between the variables based on the model. Include the values of the domain for which the model is appropriate.

To describe the relationship between the variables, we will describe the strength and direction of the correlation in context.

To determine the domain for which the model is appropriate, we will look at the domain of the actual data values and the clustering of the points to the line and consider what is reasonable within the given context.

The model shows that as the class size increases, the time a teacher is able to spend with small groups of students decreases.

This model is based on data where the class sizes range from 6 students to 26 students, so it is most appropriate to use for predictions within this domain.

The model can still be used to make predictions for class sizes outside of this domain, but the predictions become less reliable. Notice that the data on class sizes smaller than 10 are further from the line, making any prediction on smaller class sizes less reliable.

And while class sizes beyond 26 are likely to be clustered near the line based on the given data, we cannot be sure that this trend will continue without collecting more data.

For example, there may be a maximum class size for which this trend applies and after a class gets large enough the amount of time a teacher can spend may drop more significantly and be better modeled by a different type of function, like an exponential function.

Use the graph to answer the principal's statistical question.

The principal's question is, "What size should a class be for a teacher to be able to spend at least 10 minutes with students in small groups?"

A teacher is able to spend 10 minutes per small group when the class has about 21 students or less.

We could also have used the equation of the line that was given in part (b).

This shows us that the number is actually lower than 21 so a class size of 20 or fewer students may be a better prediction.